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The different solid structures or polymorphs of atomic and molecular crystals often possess different
physical and chemical properties. Structural differences between organic molecular crystal polymorphs
can affect, for example, bioavailability of active pharmaceutical formulations, the lethality of contact
insecticides, and diffusive behavior in host-guest systems. In metallic crystals, structural differences may
determine how different phases may be used in electronic device applications. Crystallization conditions
can influence polymorph selection, making an experimentally driven hunt for polymorphs difficult.
These efforts are further complicated when polymorphs initially obtained under a particular experimental
protocol “disappear” in favor of another polymorph in subsequent repetitions of the experiment. Theory
and computation can potentially play a vital role in mapping the landscape of crystal polymorphism.
Traditional methods for predicting crystal structures and investigating solid-solid phase transformation
behavior face their own challenges, and therefore, new approaches are needed. In this talk, I will show,
by leveraging concepts from mathematics, specifically geometry and topology, and quantum statistical
mechanics in combination with techniques of molecular simulation and machine learning, that new
paradigms are emerging in our ability to predict molecular crystal structures and determine kinetics of
polymorphic phase transformations. |